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Ei yksi artikkeli vielä kesää tee, mutta olen onnistunut löytämään tämän asian tiimoilta yllättävän paljon tieteellisiä ja vertaisarvioituja lähteitä. Eikä tässä ole vielä kaikki. Mutta reipas sata artikkelia on jo kyllin hyvä määrä, joten voin jo nyt laittaa ne suuremman yleisön nähtäville. Pikku hiljaa ja kovalla työllä olen onnistunut ne löytämään, joten jos joku vain suinkin hyötyy vaivannäöstäni, niin se riemastuttaisi minua kovasti.

Varsinkin kaikki ne, joille on sanottu heidän neurologisten vaivojensa olevan toiminnallisia. Suosittelen teille homekoiran tilaamista. Ei se ota, jos ei annakaan. Kyllä tämän näytön perusteella kehtaa sanoa, että homeet vaikuttavat myös hermostoon.

• Anyanwu E.C., Campbell A.W. , A. V. Neurophysiological effects of chronic indoor environmental toxic mold exposure on children. The Scientific World Journal. 2003;3:281-290.
• Anyanwu EC. Chronic environmental exposure to Alternaria tenuis may manifest symptoms of neuropsychological illnesses: a study of 12 cases. Journal of Applied Sciences and Environmental Management. 2006;9(3).
• Anyanwu E, Campbell AW, Jones J, Ehiri JE, Akpan AI. The neurological significance of abnormal natural killer cell activity in chronic toxigenic mold exposures. The Scientific World Journal. 2003;3:1128-1137.
• Anyanwu EC, Morad M, Campbell AW. Metabolism of Mycotoxins, Intracellular Functions of Vitamin B(12), and Neurological Manifestations in Patients with Chronic Toxigenic Mold Exposures. A Review. The Scientific World Journal. 2004;4:736-745.
• Anyanwu E, Ehiri J, Akpan AI. Application, effectiveness, and limitations of the electrophysiological diagnosis of neurotoxic effects of chronic environmental mycotoxins in humans . [Review]. International Journal of Adolescent Medicine & Health. 2004;16(2):107-118.
• Baldissera MD, Souza CF, Zeppenfeld CC, et al. Aflatoxin B1-contaminated diet disrupts the blood brain barrier and affects fish behavior: Involvement of neurotransmitters in brain synaptosomes. Environmental Toxicology and Pharmacology. 2018;60:45-51.
• Baldo JV, Ahmad L, Ruff R. Neuropsychological Performance of Patients Following Mold Exposure. Applied Neuropsychology. 2002;9(4):193-202.
• Baldo J, Ahmad L, Ruff R. Neuropsychological profile of patients following mold exposure: a comparison with mild traumatic brain injury. Archives of Clinical Neuropsychology. 2001;16(8):719-738.
• Benito-León J, Laurence M. The Role of Fungi in the Etiology of Multiple Sclerosis. Frontiers in Neurology. 2017;8(535).
• Berent S. Neurobehavioral toxicology: Neurobehavioral and neuropsychological perspectives, foundations, and methods (Studies on neuropsychology, development, and cognition). New York: Taylor & Francis; 2005.
• Berntsen HF, Bogen IL, Wigestrand MB, Fonnum F, Walaas SI, Moldes-Anaya A. The fungal neurotoxin penitrem A induces the production of reactive oxygen species in human neutrophils at submicromolar concentrations. Toxicology. 2017;392:64-70.
• Berntsen HF, Wigestrand MB, Bogen IL, Fonnum F, Walaas SI, Moldes-Anaya A. Mechanisms of penitrem-induced cerebellar granule neuron death in vitro: Possible involvement of GABAA receptors and oxidative processes. NeuroToxicology. 2013;35:129-136.
• Berstad K, Berstad JER. Parkinson's disease; the hibernating spore hypothesis. Medical Hypotheses. 2017;104:48-53.
• Bhat PV, Anand T, Mohan Manu T, Khanum F. Restorative effect of l-Dopa treatment against Ochratoxin A induced neurotoxicity. Neurochemistry International. 2018; 118:252-263.
• Bhat PV, Pandareesh, Khanum F, Tamatam A. Cytotoxic Effects of Ochratoxin A in Neuro-2a Cells: Role of Oxidative Stress Evidenced by N-acetylcysteine. Frontiers in Microbiology. 2016;7:1142.
• Bolla KI. Neuropsychological assessment for detecting adverse effects of volatile organic compounds on the central nervous system. In:1991.
• 18. Bolla-Wilson K, Wilson RJ, Bleecker ML. Conditioning of physical symptoms after neurotoxic exposure. Journal of occupational medicine : official publication of the Industrial Medical Association. 1988;30(9):684-686.
• Breton P, Bizot JC, Buee J, De La Manche I. Brain neurotoxicity of Penitrem A: electrophysiological, behavioral and histopathological study. Toxicon. 1998;36(4):645-655.
• Campbell AW, Thrasher JD, Gray MR, Vojdani A. Mold and Mycotoxins: Effects on the Neurological and Immune Systems in Humans. Advances in Applied Microbiology. 2004;55:375-406.
• Campbell AW, Thrasher JD, Madison RA, Vojdani A, Gray MR, Johnson A. Neural Autoantibodies and Neurophysiologic Abnormalities in Patients Exposed to Molds in Water-Damaged Buildings. Archives of Environmental Health: An International Journal. 2003;58(8):464-474.
• Carey SA, Plopper CG, Hyde DM, Islam Z, Pestka JJ, Harkema JR. Satratoxin-G from the Black Mold Stachybotrys chartarum Induces Rhinitis and Apoptosis of Olfactory Sensory Neurons in the Nasal Airways of Rhesus Monkeys. Toxicologic Pathology. 2012;40(6):887-898.
• Cavanagh JB, Holton JL, Nolan CC, Ray DE, Naik JT, Mantle PG. The Effects of the Tremorgenic Mycotoxin Penitrem A on the Rat Cerebellum. Veterinary Pathology. 1998;35(1):53-63.
• Chen JW. Territrem B, a tremorgenic mycotoxin that inhibits acetylcholinesterase with a noncovalent yet irreversible binding mechanism. The Journal of biological chemistry. 1999;274(49):34916-34923.
• Chiu IM, von Hehn CA, Woolf CJ. Neurogenic inflammation and the peripheral nervous system in host defense and immunopathology. Nature Neuroscience. 2012;15(8):1063-1067.
• Ciegler A. Tremorgenic Toxin from Penicillium palitans. Applied Microbiology. 1969;18(1):128-129.
• Cole RJ, Kirksey JW, Moore JH, Blankenship BR, Diener UL, Davis ND. Tremorgenic Toxin from Penicillium verruculosum. Applied Microbiology. 1972;24(2):248-250.
• Cole RJ, Kirksey JW, Wells JM. A new tremorgenic metabolite from Penicillium paxilli. Canadian journal of microbiology. 1974;20(8):1159-1162.
• Corps KN, Islam Z, Pestka JJ, Harkema JR. Neurotoxic, Inflammatory, and Mucosecretory Responses in the Nasal Airways of Mice Repeatedly Exposed to the Macrocyclic Trichothecene Mycotoxin Roridin A:Dose-Response and Persistence of Injury. Toxicologic Pathology. 2010;38(3):429-451.
• Costa LG, Cole TB, Coburn J, Chang Y-C, Dao K, Roqué PJ. Neurotoxicity of traffic-related air pollution. NeuroToxicology. 2017;59:133-139.
• Crago BR, Gray MR, Nelson LA, Davis M, Arnold L, Thrasher JD. Psychological, Neuropsychological, and Electrocortical Effects of Mixed Mold Exposure. Archives of Environmental Health: An International Journal. 2003;58(8):452-463.
• Dalziel JE, Finch SC, Dunlop J. The fungal neurotoxin lolitrem B inhibits the function of human large conductance calcium-activated potassium channels. Toxicology Letters. 2005;155(3):421-426.
• Dantzer R. Neuroimmune Interactions: From the Brain to the Immune System and Vice Versa. Physiological Reviews. 2018;98(1):477-504.
• Delibas N, Altuntas I, Yonden Z, Ozcelik N. Ochratoxin a reduces NMDA receptor subunits 2A and 2B concentrations in rat hippocampus: partial protective effect of melatonin. Human & experimental toxicology. 2003;22(6):335-339.
• Doi K, Uetsuka K. Mechanisms of Mycotoxin-Induced Neurotoxicity through Oxidative Stress-Associated Pathways. International Journal of Molecular Sciences. 2011;12(8):5213-5237.
• Eiser AR. Why does Finland have the highest dementia mortality rate? Environmental factors may be generalizable [Review]. Brain Research. 2017;1671:14-17.
• Eldefrawi M.E., Gant D.B., A.T. E. The GABA Receptor and the Action of Tremorgenic Mycotoxins. In: (eds) PAEea, ed. Microbial Toxins in Foods and Feeds. Boston, MA: Springer; 1990:pp 291-295.
• Empting LD. Neurologic and neuropsychiatric syndrome features of mold and mycotoxin exposure. Toxicology & Industrial Health. 2009;25(9/10):577-581.
• Fayos J, Lokensgard D, Clardy J, Cole RJ, Kirksey JW. Structure of verruculogen, a tremor producing peroxide from Penicillium verruculosum. Journal of the American Chemical Society. 1974;96(21):6785-6787.
• Fiedler N. Neuropsychological approaches for the detection and evaluation of toxic symptoms. Environmental Health Perspectives. 1996;104(Suppl 2):239-245.
• Fournier K, Baumont E, Glorennec P, Bonvallot N. Relative toxicity for indoor semi volatile organic compounds based on neuronal death. Toxicology Letters. 2017;279(Supplement C):33-42.
• Gallagher RT, Latch GCM. Production of the Tremorgenic Mycotoxins Verruculogen and Fumitremorgin B by Penicillium piscarium Westling. Applied and Environmental Microbiology. 1977;33(3):730-731.
• Gallagher RT, Finer J, Clardy J, et al. Paspalinine, a tremorgenic metabolite from Claviceps paspali Stevens et Hall. Tetrahedron Letters. 1980;21(3):235-238.
• Gant DB, Cole RJ, Valdes JJ, Eldefrawi ME, Eldefrawi AT. Action of tremorgenic mycotoxins on GABAA receptor. Life Sciences. 1987;41(19):2207-2214.
• Gay F. Bacterial toxins and Multiple Sclerosis. Journal of the Neurological Sciences. 2007;262(1–2):105-112.
• Gordon K.E. , Masotti RE, W.R. W. Tremorgenic encephalopathy: a role of mycotoxins in the production of CNS disease in humans? Canadian Journal of Neurological Sciences. 1993;20(3):237-239.
• Gordon WA, Cantor JB, Johanning E, et al. Cognitive impairment associated with toxigenic fungal exposure: A replication and extension of previous findings. Applied Neuropsychology. 2004;11(2):65-74.
• Gordon WA, Cantor JB, Spielman L, Ashman TA, Johanning E. Cognitive Impairment Associated with Toxigenic Fungal Exposure: A Response to Two Critiques. Applied Neuropsychology. 2006;13(4):251-257.
• Harding CF, Pytte C, Page K, et al. 85. Environmental mold, brain inflammation, cognitive deficits, and increased anxiety and fear. Brain, Behavior, and Immunity. 2014;40:e25.
• Harding CF, Liao D, Persaud R, Lin K, Page K, Pytte C. Environmental mold exposure, brain inflammation, and spatial memory deficits. Brain Behavior and Immunity  2015;49:e42-e42.
• Harding CF, Ryberg K, Biegon A. Exposure to environmental mold causes hippocampal inflammation and memory loss. Brain Behavior and Immunity. 2011;25:S186-S186.
• Harding CF, Ryberg K, Pytte C, Nagai M, Ali B, Denisova K. Environmental mold, brain inflammation, and memory deficits. Brain Behavior and Immunity. 2012;26:S47-S47.
• Hartman DE. Neuropsychological toxicology. Identification and assessment of human neurotoxic syndromes. 2nd ed. ed. New York: Springer; 2012.
• Horowitz J, Nagai M, Desai T, Pytte CL, Harding C. Exposure to the mold Stachybotrys alters microglial morphology differentially in CA1 and CA2-3 of the dorsomedial hippocampus. Brain Behavior and Immunity. 2015;49:e32-e32.
• Hotujac L, Stern P. Pharmacological examination of verruculogen induced tremor. Acta medica Iugoslavica. 1974;28(3):223-229.
• Hotujac L, Muftić RH, Filipović N. Verruculogen: a New Substance for Decreasing of GABA Levels in CNS. Pharmacology. 1976;14(4):297-300.
• Inamdar AA, Hossain MM, Bernstein AI, Miller GW, Richardson JR, Bennett JW. Fungal-derived semiochemical 1-octen-3-ol disrupts dopamine packaging and causes neurodegeneration. 2013;110(48):19561-19566.
• Inamdar AA, Masurekar P, Bennett JW. Neurotoxicity of Fungal Volatile Organic Compounds in Drosophila melanogaster. Toxicological Sciences. 2010;117(2):418-426.
• Islam Z, Amuzie CJ, Harkema JR, Pestka JJ. Neurotoxicity and inflammation in the nasal airways of mice exposed to the macrocyclic trichothecene mycotoxin roridin a: kinetics and potentiation by bacterial lipopolysaccharide coexposure. Toxicological sciences : an official journal of the Society of Toxicology. 2007;98(2):526-541.
• Islam Z, Hegg CC, Bae HK, Pestka JJ. Satratoxin G–Induced Apoptosis in PC-12 Neuronal Cells is Mediated by PKR and Caspase Independent. Toxicological Sciences. 2008;105(1):142-152.
• Jortner BS, Ehrich M, Katherman AE, Huckle WR, Carter ME. Effects of Prolonged Tremor Due to Penitrem a in Mice. Drug and Chemical Toxicology. 1986;9(2):101-116.
• Kanu I. Chronic exposure to Alternaria tenuis, Pullularia pullulans, and Epicoccum nigrum may lead to symptoms of neuropsychological illnesses: evidence from a comprehensive evaluation.(Clinical report). The Internet Journal of Toxicology. 2006.
• Karunasena E, Larraaga MD, Simoni JS, Douglas DR, DC. S. Building-Associated Neurological Damage Modeled in Human Cells: A Mechanism of Neurotoxic Effects by Exposure to Mycotoxins in the Indoor Environment. Mycopathologia. 2010(Jun 13).
• Kelly-KA, Miller-DB, O'Callaghan-JP. Exploring the relationship between neuroinflammation and neurotoxicity. Toxicologist. 2014 Mar;;138(1):186-187.
• Kilburn KH. Indoor Mold Exposure Associated with Neurobehavioral and Pulmonary Impairment: A Preliminary Report. Archives of Environmental Health. 2003;58(7):390-398.
• Lewis Peter R, Donoghue Michael B, Cook Lucy, V GL, D HA. Tremor syndrome associated with a fungal toxin: sequelae of food contamination. The Medical Journal of Australia. 2005;182(11):582-584.
• Ling KH. Territrems, Tremorgenic Mycotoxins Isolated from Aspergillus Terreus. Journal of Toxicology: Toxin Reviews. 1994;13(3):243-252.
• Ling KH, Yang CK, Peng FT. Territrems, tremorgenic mycotoxins of Aspergillus terreus. Applied and Environmental Microbiology. 1979;37(3):355-357.
• Longland CL. The mycotoxin paxilline inhibits the cerebellar inositol 1,4,5-trisphosphate receptor. European Journal of Pharmacology. 2000;408(3):219-225.
• Mathur M, Johnson CE, Sze G. Fungal Infections of the Central Nervous System. Neuroimaging Clinics of North America. 2012;22(4):609-632.
• Moldes-Anaya AS, Fonnum F, Eriksen GS, Rundberget T, Walaas SI, Wigestrand MB. In vitro neuropharmacological evaluation of penitrem-induced tremorgenic syndromes: Importance of the GABAergic system. Neurochemistry International. 2011;59(7):1074-1081.
• Morris G, Berk M, Walder K, Maes M. The Putative Role of Viruses, Bacteria, and Chronic Fungal Biotoxin Exposure in the Genesis of Intractable Fatigue Accompanied by Cognitive and Physical Disability. Molecular Neurobiology. 2016;53(4):2550-2571.
• Nishiyama M, Kuga T. Central effects of the neurotropic mycotoxin fumitremorgin A in the rabbit. () Effects on the spinal cord. JpnJPharmacol The Japanese Journal of Pharmacology. 1989;50(2):167-173.
• Nishiyama M, Kuga T. Central effects of the neurotropic mycotoxin fumitremorgin A in the rabbit. (II). Effects on the brain stem. JpnJPharmacol The Japanese Journal of Pharmacology. 1990;52(2):201-208.
• Norris PJ, Smith CCT, DeBelleroche J, Bradford HF, Mantle PG, Thomas AJ. Actions of tremorgenic fungal toxins on neurotransmitter release. J Neurochem. 1980;34 (?):33-42.
• O'Callaghan JP, Kelly KA, VanGilder RL, Sofroniew MV, Miller DB. Early Activation of STAT3 Regulates Reactive Astrogliosis Induced by Diverse Forms of Neurotoxicity. PLoS ONE. 2014;9(7):1-17.
• Otto D, Molhave L, Rose G, Hudnell HK, House D. Neurobehavioral and sensory irritant effects of controlled exposure to a complex mixture of volatile organic compounds. Neurotoxicology and Teratology. 1990;12(6):649-652.
• Otto DA. Assessment of Neurobehavioral Response in Humans to Low-Level Volatile Organic Compound Sourcesa. Annals of the New York Academy of Sciences. 1992;641(1):248-260.
• Page K, Lopez A, Normand E, et al. 50. Exposure to environmental mold affects interleukin-1β expression and survival of newborn neurons. Brain Behavior and Immunity. 2014;40 (September):pp.e15-e15.
• Paradells S, Rocamonde B, Llinares C, et al. Neurotoxic effects of ochratoxin A on the subventricular zone of adult mouse brain. Journal of Applied Toxicology. 2014;35(7):737-751.
• Pisa D, Alonso R, Jiménez-Jiménez FJ, Carrasco LR. Fungal infection in cerebrospinal fluid from some patients with multiple sclerosis. European Journal of Clinical Microbiology & Infectious Diseases. 2012;32:795-801.
• Purzycki CB, Shain DH. Fungal toxins and multiple sclerosis: A compelling connection. Brain Research Bulletin. 2010;82(1):4-6.
• Ratnaseelan AM, Tsilioni I, Theoharides TC. Effects of Mycotoxins on Neuropsychiatric Symptoms and Immune Processes. Clinical Therapeutics. 2018.
• Ravindran J, Agrawal M, Gupta N, Lakshmana Rao PV. Alteration of blood brain barrier permeability by T-2 toxin: Role of MMP-9 and inflammatory cytokines. Toxicology. 2011;280:44-52.
• Reis J. Multiple Sclerosis: airborne environmental triggers and the ‘bacterial toxins hypothesis’, a credible synthesis? Journal of the Neurological Sciences. 2015;357, Supplement 1:e509.
• Rey NL, Wesson DW, Brundin P. The olfactory bulb as the entry site for prion-like propagation in neurodegenerative diseases. Neurobiology of Disease. 2018;109:226-248.
• Sava V, Reunova O, Velasquez A, Harbison R, Sánchez-Ramos J. Acute neurotoxic effects of the fungal metabolite ochratoxin-A. NeuroToxicology. 2006;27(1):82-92.
• Sava V, Reunova O, Velasquez A, Sanchez-Ramos J. Can low level exposure to ochratoxin-A cause parkinsonism? Journal of the Neurological Sciences. 2006;249(1):68-75.
• Sava V, Velasquez A, Song S, Sanchez-Ramos J. Adult Hippocampal Neural Stem/Progenitor Cells In Vitro Are Vulnerable to the Mycotoxin Ochratoxin-A. Toxicological Sciences. 2007;98(1):187-197.
• Schafflick D, Kieseier BC, Wiendl H, Meyer zu Horste G. Novel pathomechanisms in inflammatory neuropathies. Journal of Neuroinflammation. 2017;14:232.
• Schroeder HW, Cole RJ, Hein H, Kirksey JW. Tremorgenic Mycotoxins from Aspergillus Caespitosus. Applied Microbiology. 1975;29(6):857–858.
• Selala MI, Daelemans F, Schepens PJC. Fungal Tremorgens: The Mechanism Of Action Of Single Nitrogen Containing Toxins - A Hypothesis. Drug and Chemical Toxicology. 1989;12(3-4):237-257.
• Shoemaker RC, House D, Ryan JC. Structural brain abnormalities in patients with inflammatory illness acquired following exposure to water-damaged buildings: A volumetric MRI study using NeuroQuant®. Neurotoxicology and Teratology. 2014;45:18-26.
• R. S. Neurotoxicity in Neuropsychology. In: Schoenberg M. SJe, ed. The Little Black Book of Neuropsychology. Boston, MA: Springer; 2011.
• Singer R. Forensic evaluation of a mold (repeated water intrusions) neurotoxicity case. Archives of Clinical Neuropsychology. (20 Tarkista):808.
• Singer R. Neurotoxicity can produce “MS-like” symptoms. Journal of Clinical and Experimental Neuropsychology. 1990(12):68.
• Singer R. In: Schoenberg MR, Scott JG, eds. The Little Black Book of Neuropsychology: A Syndrome-Based Approach. Boston, MA: Springer US; 2011:813-838.
• Sobotka TJ, Brodie RE, Spaid SL. Neurobehavioral Studies of Tremorgenic Mycotoxins Verruculogen and Penitrem A. Pharmacology. 1978;16(5):p. 287-294.
• Stockmann-Juvala H. Neuro- and Immunotoxic Effects of Fumonisin B1 in Cells. Helsinki: Faculty of Pharmacy, University of Helsinki; 2007.
• Stockmann-Juvala H, Naarala J, Loikkanen J, Vähäkangas K, Savolainen K. Fumonisin B1-induced apoptosis in neuroblastoma, glioblastoma and hypothalamic cell lines. Toxicology. 2006;225(2):234-241.
• Suzuki S, Kikkawa K, M. Y. Abnormal behavioral effects elicited by a neurotropic mycotoxin, fumitremorgin A in mice. Journal of Pharmacobio-Dynamics. 1984;7(12):935-942.
• Valdes James J., E. CJ, J. aCR. Aflatrem: A Tremorgenic Mycotoxin with Acute Neurotoxic Effects. Environmental Health Perspectives. 1985;Vol. 62 (Oct., 1985), pp. 459-463:pp. 459-463.
• von Tobel JS, Antinori P, Zurich M-G, et al. Repeated exposure to Ochratoxin A generates a neuroinflammatory response, characterized by neurodegenerative M1 microglial phenotype. NeuroToxicology. 2014;44:61-70.
• Yamazaki M, Suzuki S. Toxicology of tremorgenic mycotoxins, fumitremorgin A and B. Developments in toxicology and environmental science. 1986;12:273-282.
• Yamazaki M, Fujimoto H, Kawasaki T. The structure of a tremorgenic metabolite from aspergillus fumigatus fres., fumitremorgin a. Tetrahedron Letters. 1975;16(14):1241-1244.
• Yamazaki M, Sasago K, Miyaki K. The structure of fumitremorgin B (FTB), a tremorgenic toxin from Aspergillus fumigatus Fres. Journal of the Chemical Society, Chemical Communications. 1974(10):408-409.
• Yang NJ, Chiu IM. Bacterial Signaling to the Nervous System through Toxins and Metabolites. Journal of Molecular Biology. 2017;429(5):587-605.
• Yoshizawa T, Morooka N, Sawada Y, Udagawa S-I. Tremorgenic Mycotoxin from Penicillium paraherquei. Applied and Environmental Microbiology. 1976;32(3):441-442.
• Young C, Seung Hee C, Dai Eun S. Note : Presynaptic Effects of Verruculogen on Gamma - Aminobutyric Acid ( GABA ) Uptake and Release in Rat Brain. Biochemistry and Molecular Biology Reports. 1994;27(4):353.
• Zhang X, Boesch-Saadatmandi C, Lou Y, Wolffram S, Huebbe P, Rimbach G. Ochratoxin A induces apoptosis in neuronal cells. Genes & Nutrition. 2009;4(1):41-48.
• Zurich M-G, Honegger P. Ochratoxin A at nanomolar concentration perturbs the homeostasis of neural stem cells in highly differentiated but not in immature three-dimensional brain cell cultures. Toxicology Letters. 2011;205(2):203-208.

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• Asano S, Bratz IN, Berwick ZC, Fancher IS, Tune JD, Dick GM. Penitrem A as a Tool for Understanding the Role of Large Conductance Ca(2+)/Voltage-Sensitive K(+) Channels in Vascular Function. The Journal of Pharmacology and Experimental Therapeutics. 2012;342(2):453-460.
• Carratú M. R., Belmadani A., Cuomo V., E CE. Potassium channel modulation by the pseudopeptide ochratoxin A in rat nerve fibers. Journal of neuroscience research. 1998;53(3):312–317.
• Dalziel JE, Finch SC, Dunlop J. The fungal neurotoxin lolitrem B inhibits the function of human large conductance calcium-activated potassium channels. Toxicology Letters. 2005;155(3):421-426.
• DeFarias FP, Carvalho MF, Lee SH, Kaczorowski GJ, Suarez-Kurtz G. Effects of the K+ channel blockers paspalitrem-C and paxilline on mammalian smooth muscle. European Journal of Pharmacology. 1996;314(1):123-128.
• Goda AA, Naguib KM, Mohamed MM, et al. Astaxanthin and Docosahexaenoic Acid Reverse the Toxicity of the Maxi-K (BK) Channel Antagonist Mycotoxin Penitrem A. Marine Drugs. 2016;14(11):208.
• Imlach WL, Finch SC, Dunlop J, Dalziel JE. Structural determinants of lolitrems for inhibition of BK large conductance Ca2+-activated K+ channels. European Journal of Pharmacology. 2009;605(1):36-45.
• Imlach WL, Finch SC, Dunlop J, Meredith AL, Aldrich RW, Dalziel JE. The Molecular Mechanism of “Ryegrass Staggers,” a Neurological Disorder of K+ Channels. Journal of Pharmacology and Experimental Therapeutics. 2008;327(3):657- 664.
• Imlach W, Finch S, Zhang Y, Dunlop J, Dalziel J. Mechanism of action of lolitrem B, a fungal endophyte derived toxin that inhibits BK large conductance Ca2+-activated K+ channels. Toxicon. 2011;57(5):686-694.
• Knaus HG, McManus OB, Lee SH, et al. Tremorgenic indole alkaloids potently inhibit smooth muscle high-conductance calcium-activated potassium channels. Biochemistry. 1994;33(19):5819-5828.
• Li G, Cheung DW. Effects of paxilline on K+ channels in rat mesenteric arterial cells. European Journal of Pharmacology. 1999;372(1):103-107.
• Mikkola R, Andersson M, Kredics L, Grigoriev P, Sundell N, Salkinoja-Salonen M. 20
  Residue and 11-residue peptaibols from the fungus Trichoderma longibrachiatum are
  synergistic in forming Na + /K + -permeable channels and adverse action towards mammalian
  cells. The FEBS journal. 2012;279.
• Rasimus-Sahari S, Teplova VV, Andersson MA, et al. The Peptide Toxin Amylosin of Bacillus amyloliquefaciens from Moisture-Damaged Buildings Is Immunotoxic, Induces Potassium Efflux from Mammalian Cells, and Has Antimicrobial Activity. Applied and Environmental Microbiology. 2015;81(8):2939-2949.
• Sanchez M, McManus OB. Paxilline Inhibition of the Alpha-subunit of the High-conductance Calcium-activated Potassium Channel. Neuropharmacology. 1996;35(7):963-968.
• Saris N-EL, Andersson MA, Mikkola R, et al. Microbial toxin’s effect on mitochondrial survival by increasing K+ uptake. Toxicology and Industrial Health. 2009;25(7):441-446.
• Sausbier M, Hu H, Arntz C, et al. Cerebellar ataxia and Purkinje cell dysfunction caused by Ca2+-activated K+ channel deficiency. Proceedings of the National Academy of Sciences of the United States of America. 2004;101(25):9474-9478.
• Tonshin AA, Teplova VV, Andersson MA, Salkinoja-Salonen MS. The Fusarium mycotoxins enniatins and beauvericin cause mitochondrial dysfunction by affecting the mitochondrial volume regulation, oxidative phosphorylation and ion homeostasis. Toxicology. 2010;276(1):49-57.
• Zhou Y, Lingle CJ. Paxilline inhibits BK channels by an almost exclusively closed-channel block mechanism. The Journal of General Physiology. 2014;144(5):415-440.
• Zhou Y, Tang Q-Y, Xia X-M, Lingle CJ. Glycine311, a determinant of paxilline block in BK channels: a novel bend in the BK S6 helix. The Journal of General Physiology. 2010;135(5):481-494. 

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